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Nov 21, 2011 - ABSTRACT: Structures of neutral metalАdibenzene complexes, M(C6H6)2 (M = ScАZn), are investigated by using MшllerА. Plesset second ...
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Intercalation of Transition Metals into Stacked Benzene Rings: A Model Study of the Intercalation of Transition Metals into Bilayered Graphene Il Seung Youn,† Dong Young Kim,† N. Jiten Singh,† Sung Woo Park,† Jihee Youn,† and Kwang S. Kim*,† †

Department of Chemistry and Department of Physics, Pohang University of Science and Technology, Pohang 790-784, Korea

bS Supporting Information ABSTRACT: Structures of neutral metal dibenzene complexes, M(C6H6)2 (M = Sc Zn), are investigated by using Møller Plesset second order perturbation theory (MP2). The benzene molecules change their conformation and shape upon complexation with the transition metals. We find two types of structures: (i) stacked forms for early transition metal complexes and (ii) distorted forms for late transition metal ones. The benzene molecules and the metal atom are bound together by δ bonds which originate from the interaction of π-MOs and d orbitals. The binding energy shows a maximum for Cr(C6H6)2, which obeys the 18-electron rule. It is noticeable that Mn(C6H6)2, a 19-electron complex, manages to have a stacked structure with an excess electron delocalized. For other late transition metal complexes having more than 19 electrons, the benzene molecules are bent or stray away from each other to reduce the electron density around a metal atom. For the early transition metals, the M(C6H6) complexes are found to be more weakly bound than M(C6H6)2. This is because the M(C6H6) complexes do not have enough electrons to satisfy the 18-electron rule, and so the M(C6H6)2 complexes generally tend to have tighter binding with a shorter benzene metal length than the M(C6H6) complexes, which is quite unusual. The present results could provide a possible explanation of why on the Ni surface graphene tends to grow in a few layers, while on the Cu surface the weak interaction between the copper surface and graphene allows for the formation of a single layer of graphene, in agreement with chemical vapor deposition experiments.

bis(benzene) first-row transition metal complexes (Bz2M; M = Sc Zn) using ab initio calculations. Even though there have been many theoretical studies of Bz2M, they used only density functional theory (DFT) methods,2,11,12,23,26,28,39,41,48,51 which have not been well tested for the interactions between benzene and central metal atoms. Thus, we have carried out MP2 calculations using the aug-cc-pVDZ (aVDZ) and aug-cc-pVTZ (aVTZ) basis sets. Since the highest occupied molecular orbitals (HOMO) are doubly degenerate, the Bz2M complexes maintain uniformly stacked structures for M = Sc Cr. Those structures support the 18-electron rule in organometallics. Even though Bz2Mn has 19 electrons, it has the same structure with Bz2Cr due to the nature of the HOMO, which diffuses the extra electron. For Bz2M where M = Fe Zn, the complexes cannot have wellordered stacking forms because of the instability caused by too many excess electrons. Hence, two benzene molecules stray from each other or one benzene molecule is bent, changing the electron donation type from η6 to η4 or η2. In order to compare the structural properties of the sandwiched complexes (Bz2M) with those of the corresponding complexes having only one benzene molecule (BzM), we also examined their different natures in molecular bonding character. The critical interaction in BzM complexes is the one between π-MOs of benzene and d(xz) or d(yz) orbitals of the metal atom.10,33 This type of σ-bonding itself is stronger than δ bonding; yet, the BzM

is(η6-benzene)chromium, Cr(C6H6)2, is an 18-electron closed-shell compound including two benzene rings with a chromium atom at the center, which is one of the most wellknown examples of organometallic sandwich complexes. Since its discovery by Fischer and Hafner,1 numerous experimental and theoretical studies have been carried out to investigate how two benzene rings and a chromium atom interact and what kind of structure the complex forms.2 13 Cr(C6H6)2 has the two eclipsed stacked forms of two benzene rings with the chromium atom placed at the midpoint of the two benzene centroids. On the basis of these studies, researchers have investigated electronic properties of the Cr(C6H6)2 complex and the related cation complexes for a possible use as spin trap device or for the extension to carbon nanotubes and graphene.14 37 In addition, other similar molecules with transition metals have been studied for the same purpose,38 52 and the analogs such as graphene metal hybrid materials have been utilized for electronic devices, biosensors, and the removal of hazardous materials.53 56 Nevertheless, the structure of the complexes of transition metals has not been properly studied at the high level of theory yet. For Cr(C6H6)2, the π character of each benzene interacts with d orbitals in the chromium atom; π-molecular orbitals (MOs) of benzene (Bz) molecules interact with the d(xy) and d(x2 y2) orbitals in the chromium atom, forming the δ bond. In this case, the π π interaction57 68 between two benzene molecules is very small because of their large separation, while the metal π interaction69 74 between a metal atom and benzene molecules is dominant. Here, we investigated the structures of

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r 2011 American Chemical Society

Received: September 20, 2011 Published: November 21, 2011 99

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Table 1. MP2/aVTZ Results for the BzM Complexes metal

Figure 1. Breathing mode in Bz2M.

complexes do not satisfy the 18-electron requirement because a ligand, benzene, donates electrons from only one side. On the other hand, two benzene molecules donate electrons, and then π-MOs interact with a metal atom from both above and below, satisfying the 18-electron requirement with stronger binding in Bz2M. This results in a shorter distance between the metal atom and the benzene centroid (dM Bz) in the Bz2M complexes than in the corresponding BzM ones for M = Sc Mn, except for Bz2Ti and Bz2Cr. We performed ab initio calculations using the Gaussian 09 package.75 To search for low-lying energy structures, we have dealt with several probable structures based on the structure of Cr(C6H6)2 with point group D6h. In order to find the proper spin multiplicity of each metal atom in each complex, we optimized all structures with symmetry adaptation at each defined spin multiplicity by using MP2 with the aug-cc-pVDZ (aVDZ) basis set for carbon and hydrogen atoms and the CRENBL effective core potentials (ECP)76 for transition metal atoms. The frequency analysis was done to confirm the minimum-energy structures. The structures were reoptimized with basis set superposition error (BSSE) correction. The single point energy calculations were performed at the MP2 level of theory with the aug-cc-pVTZ (aVTZ) and CRENBL ECP basis sets. The complete basis set limit energies77,78 were not made because of possible errors arising from large BSSEs at the aVDZ level. We studied natural bonding orbital (NBO) charges, binding energies (negative value of the interaction energies: ΔE), distances between the benzene and metal atom, and frequencies of a breathing mode (Figure 1).

’ DETERMINATION OF THE MOST STABLE SPIN CONFIGURATIONS The possible spin multiplicities of each metal complex are 2 and 4 for Sc and Co; 1, 3, and 5 for Ti and Fe; 2, 4, and 6 for V and Mn; 1, 3, 5, and 7 for Cr; 1 and 3 for Ni; 2 for Cu; and 1 for Zn in the complexes. In the Bz2M case, each complex has the most stable structure in the lowest spin multiplicity. The singlet and the triplet Fe complexes have similar energies. The spin multiplicity of each BzM complex at the lowest energy is dependent on the kind of metal atom: Sc, V, and Fe prefer 4, 4,

spin multiplicity

(Å)

Bz

ΔE

NBO charge

(kcal mol 1)

of metals (a.u.)a

Sc

C2v

4

1.923

82.3

0.875

Ti

C2v

1

1.604

84.4

1.060

V

C1

4

1.712

37.4

0.996

Cr

C3v

1

1.511

208.7

0.697

Mn

C1

2

1.887

48.2

0.772

C1

4

1.610

54.8

1.375

C1 C2v

3 2

1.512 1.503

30.8 84.9

1.239 0.525

Fe Co

a

dM

point group

Ni

C3v

1

1.441

103.2

0.778

Cu

C1

2

3.305

1.9

0.080

Zn

Cs

1

3.559

2.0

0.045

NBO charges are calculated at the MP2/aVDZ level.

and 3, respectively, and the others prefer the lowest spin multiplicities (see Supporting Information).

’ STRUCTURES OF BzM COMPLEXES In the BzM complexes, geometry optimization was performed for several different spin multiplicities. These data are summarized in Table 1 (MP2/aVTZ) and in Table S1 (MP2/aVDZ) in the Supporting Information. Several spin states of BzM (M = Sc, Ti, Cr, Mn, and Co) show attractive interactions. The lowest spin multiplicities exhibit stronger binding for all BzM’s except for M = Sc, V, Mn, and Fe; for M = Sc, V, and Fe, each spin multiplicity of 4, 4, and 3 shows stronger binding. The spin multiplicity of 2 in BzMn shows the strongest binding at the MP2/aVDZ level, but the spin multiplicity of 4 does at the MP2/aVTZ level. As shown in Figure 2, the structures of BzM complexes are based on the structure of point group C6v. Only the BzV has a bent benzene molecule below the metal atom. Not only the shape of benzene but also the dM Bz’s differ from each other. The primary interactions, which give bonding character to a complex, are benzene π orbitals with metal d(yz), d(zx), and d(z2) orbitals (Figure 3b 3 and 4). Other important interactions are ones between π* orbitals (top orbitals in Figure 3a) and the rest, two d orbitals. While those interactions lead to a bonding property, one between the π orbital shown in the bottom of Figure 3a and an s orbital brings out antibonding character. The key point is that there are stabilization and destabilization of some orbitals during the formation of the molecular orbitals (MOs). Five d orbitals locate differently depending on a metal atom and its spin state. In the BzSc case, a scandium atom with a spin multiplicity of 4 has occupied frontier d(yz), d(z2), and s orbitals, and other vacant 3d orbitals. Thus, when they form the BzSc complex, high-lying d(xy) and d(x2 y2) orbitals interact with π* orbitals, which are in similar energy level, stabilizing the complex. A similar effect is caused from the formation of 3. On the other hand, the most stable π orbital is destabilized by interacting with the s orbital, forming the antibonding highest occupied molecular orbital (HOMO), 1. This antibonding HOMO causes relatively long distance dM Bz, 1.92 Å. The BzTi complex resembles the situation, but there is not a large advantage to forming 3 or forming 1 as the HOMO. This results in similar binding energies for BzSc and BzTi, but shorter dM Bz in BzTi, 1.60 Å. For BzV, a big energy loss comes from the 100

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Figure 2. MP2/aVTZ predicted structures of BzM complexes.

graphene, in agreement with chemical vapor deposition (CVD) experiments.78 80 In addition, this significant difference in π metal interactions between different metal atoms could be useful for ion sensing, such as conductance measurement through carbon-based electrodes such as graphene nanoribbons.81 83

Figure 3. π orbitals of a benzene molecule (a) and important orbitals in BzM complexes (b).

formation of 3, which includes destabilization of d(yz) and d(zx) orbitals, leading to a small binding energy. All 2 and 3 orbitals with stabilization of π*, d(zx), d(yz), and d(x2 y2) orbitals are occupied in BzCr, and thus a benzene molecule and a chromium atom bind strongly. Some cases such as BzMn and BzFe cannot form bonding 2 or 3 orbitals due to a big difference in energy level between π* and d orbitals, or they fail to gain big stabilization due to the same reason in spite of the formation of 2 and 3. A similar effect occurs intensively in BzCu and BzZn because their valence orbitals are fully occupied, so that extra electrons from a benzene molecule give rise to repulsion. Despite a big energy level difference, the Co and the Ni complexes form 2 and 3, which give great stabilization of the π* orbitals and thus stronger binding energies than other BzM (M = Mn, Fe, Cu, and Zn). The above analysis explains why the dM Bz is small for M = Sc Ni (1.4 1.9 Å), while the dM Bz is large for M = Cu and Zn (3.305 and 3.559 Å, respectively). The small dM Bz’s are from the bonding 2 and 3, but the large ones are from the electron repulsion and the antibonding 1. This indicates that on the Ni surface graphene tends to grow in a few layers, while on the Cu surface the weak interaction between the copper surface and graphene would lead to the formation of a single layer of

’ STRUCTURES OF Bz2M COMPLEXES In Bz2M complexes, except for Bz2Sc of point group Cs, the symmetry is broken in all complexes. Nevertheless, the structures of early transition metal complexes (Bz2Sc Bz2Mn) are based on D6h-like structures. On the other hand, the late transition metal complexes (Bz2Fe Bz2Zn) have structures in which two distorted benzene rings stray away from each other (Figure 4). Notable points in structures of the Bz2M complexes are the dM Bz and the shape and arrangement of benzene molecules in each complex; while the Bz2M complexes of early transition metals have their benzene molecules intact, as in the corresponding BzM complexes, a benzene molecule in the late transition metal complexes stray away from each other or one of them is severely distorted, as compared to the corresponding BzM complexes (Figures 2 and 4). This is due to the well-known 18-electron rule, which indicates that the number of electrons from the ligands and the metal atom may be summed up toward 18 to form a stable metal complex. The ligands are two benzene molecules here, and the metal atoms are first row transition metals. In each Bz2M complex, one benzene ring donates six π electrons, and a metal atom has d electrons. Thus, the total number of electrons contributing to the bonding characters between two benzene rings and a metal is 6  2 + d electrons. Table 2 gives MP2/aVTZ results for the Bz2M complexes. This analysis implies that in the range from Bz2Sc to Bz2Cr, d electrons occupying bonding orbitals lead to strong interactions. These bonding orbitals consist of π orbitals of the benzene molecules and d(xy) and d(x2 y2) orbitals of the metal, resulting in δ bonding orbitals, as shown in Figure 5. This explains why the Bz2Cr complex has the largest binding energy. This explanation is confirmed by comparing the calculation results of Bz2V , Bz2Cr , and Bz2Mn+; the MP2/aVDZ and MP2/aVTZ results show that Bz2V (200 kcal mol 1 and not converged) and Bz2Mn+ (242 kcal mol 1 and 241 kcal mol 1), which are isoelectronic to Bz2Cr (323 kcal mol 1 and 342 kcal mol 1), have larger binding energies than Bz2V (173 kcal mol 1 and 193 kcal mol 1) and Bz2Mn (181 kcal mol 1 and 167 kcal mol 1), respectively, while Bz2Cr (200 kcal mol 1 and 213 kcal mol 1) has a smaller binding energy than its neutral form. 101

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Figure 4. MP2/aVTZ predicted structures of the Bz2M complexes.

Table 2. MP2/aVTZ Results for the Bz2M Complexesa dM

spin metal multiplicity (dBz2M

Figure 5. δ bonding orbitals in Bz2M complexes with point group D6h.

ΔE

Bz

ΔΔE

freq.

dBzM) (Å) (kcal mol 1) (kcal mol 1)b (cm 1)c

Sc

2

1.913 ( 0.010)

98.2

+66.4

234

Ti

1

1.732 (+0.128)

191.0

22.2

262 395

V

2

1.532 ( 0.181)

192.6

117.8

Cr

1

1.589 (+0.078)

341.7

+75.7

285

Mn

2

1.473 ( 0.137)

167.2

57.6

337

Fe

1

1.377 ( 0.135), 2.049d

234.8

173.1

e

Ni

1

1.743 (+0.302), 2.251d

132.7

+73.7

e

Cu

2

2.437f ( 0.868), 3.672

9.8

6.0

e

Zn

1

3.462,g 3.448g ( 0.111)

7.0

3.0

e

a

Bz2Co was not optimized due to the convergence problem. b Cooperative binding energy difference: ΔΔE = ΔE(Bz2M) 2  ΔE(BzM) c Frequencies were calculated at the MP2/aVDZ level without BSSE correction. d Average distance between a metal and two nearest carbon atoms of the upper benzene. e The breathing mode is not defined. f Average distance between a metal and two nearest carbon atoms of each benzene. g Distance between Zn and each benzene centriod.

According to the MO analysis, it is expected that the dM Bz is shorter in the Bz2M than in the corresponding BzM for M = Sc Cr. The Bz2Ti and Bz2Cr, however, show slightly longer dM Bz in the Bz2M. In the BzTi, all 2 and 3 orbitals are formed and are fully occupied, while δ bonding orbitals in Bz2Ti are only partially occupied. Thus, even if Bz2Ti shows stronger binding due to benzene stacking, it cannot obtain the full advantage of a decrease in dM Bz. It is also expected that the dM Bz in Bz2M is the shortest in Bz2V and Bz2Cr due to the fact that 17 and 18 electrons fully occupy the orbitals in Figure 5. However, the dM Bz of Bz2Cr is slightly longer than that of Bz2V, even though the HOMO is a δ bonding orbital. This slight deviation from the dM Bz tendency may arise from the slightly negative charge accumulated on the chromium atom due to its large electron affinity (65 kJ mol 1) as compared with the smaller electron affinity of V (51 kJ mol 1; Table 3). This negative charge of the metal repels the negative charges on carbon atoms in benzene molecules. On the other hand, despite a 19-electron environment, the dM Bz of Bz2Mn is the shortest among the five complexes, and the extent of the decrease for BzMn is also large. Of course, the structure itself is less stable than any Bz2M of early transition metals, except for Bz2Sc, based on the small binding energy of 167 kcal mol 1 for Bz2Mn. As shown in Figure 6, a peculiar shape of the HOMO of Bz2Mn, however, can dissipate electrons out of the central atom, and the complex is able to mitigate the electron repulsions. In fact, the positive NBO charge on the Mn atom in Table 3 supports the notion that Bz2Mn dissipates electrons effectively (the electron affinity of Mn is ∼0 kJ mol 1). The intercalation of FeCl3 inside the bilayer has recently been used for device fabrication.84 It would be an interesting issue

Table 3. dM Bz’s, Atomic Radii and NBO Charges of Metal in Bz2M Complexes with Point Group of D6h and BzM Complexes (M = Sc - Mn).a dM

atomic radius of metal

a

metal atoms (Å)

(dBz2M

Bz

dBzM) (Å)

Bz2M

BzM

Sc

2.090

1.913 ( 0.010)

1.121

0.875

Ti

2.000

1.732 (+0.128)

0.829

1.060

V Cr

1.920 1.850

1.532 ( 0.180) 1.589 (+0.078)

0.216 0.076

0.996 0.697

Mn

1.790

1.473 ( 0.137)

0.015

1.375

NBO charge of metal atoms (a.u.).

whether a single transition metal layer could be obtained inside bilayer graphene. In this regard, the metal dibenzene structures could give interesting information for intercalated metal inside bilayered graphene. The complexes of the late transition metals would be highly unstable if they maintain D6h-like structure because in this case the number of electrons is larger than 18. Hence, the structures need to be distorted; one of benzene molecules strays so as not to donate all 6 electrons, donating fewer electrons to the central 102

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surface and graphene allows for the formation of a single layer of graphene, in agreement with CVD experiments.

’ ASSOCIATED CONTENT

bS

Supporting Information. Discussion on the MP2/aVDZ results for BzM and Bz2M. This material is available free of charge via the Internet at http://pubs.acs.org.

Figure 6. HOMO of Bz2Mn with point group D6h.

’ AUTHOR INFORMATION

atom. Indeed, in the case of Bz2Cu, it is interesting to note that since the interaction between Cu and Bz is very weak, the π-H interaction85,86 is dominant between two benzene molecules, and the structure is no longer a stacked form.

Corresponding Author

’ DISPERSION INTERACTION FOR BzCu AND BzZn COMPLEXES Tables 1 and 2 present that Cu and Zn complexes show very weak binding (1.9 9.8 kcal mol 1) in both BzM and Bz2M complexes. The origin of these weak binding energies can be deduced from the NBO charges of metals. The NBO charges of Cu and Zn are 0.08 and 0.05, respectively, indicating that there is no charge transfer from a metal atom to a benzene molecule in each complex. Hence, these weak binding energies of BzCu and BzZn are mainly due to the dispersion interaction. Note that the dispersion interaction is overestimated at the MP2 level of theory. To clarify this problem, we further performed the calculation at the level of coupled cluster theory with the inclusion of single and double excitations and perturbative inclusion of triple excitations (CCSD(T)) with aVDZ basis set using the Molpro package87 for BzM (M = Cu and Zn). The binding energies with BSSE correction are 1.3 kcal mol 1 for BzCu and 1.0 kcal mol 1 for BzZn at the level of CCSD(T)/aVDZ. Note that the MP2/aVTZ calculation results give 1.9 and 2.0 kcal mol 1 for BzCu and BzZn, respectively. Hence, in these cases, the MP2 level of theory gives a slightly overestimated dispersion interaction in comparison with the CCSD(T) level of theory. In summary, we carried out a systematic study of Bz2M complexes as compared with the corresponding BzM complexes. The results show sandwich structures for early transition metal complexes, while such sandwich structures are broken for late transition metal ones. The dM Bz in Bz2M with doubly degenerate δ bonding orbitals tends to decrease from M = Sc to M = V. It is quite interesting that even though the second coordination generally gives a longer coordination distance with smaller coordination energy than the first coordination, the present second coordination gives a shorter coordination distance with a larger coordination energy for the early transition metals because of the 18-electron rule. Unlike the Bz2Cr, which gives some exception due to the negative NBO charge of Cr, the Bz2Mn results in decreased dM Bz because of the diffuse HOMO. Structures of Bz2M for late transition metals are distorted to avoid the instability caused by too many electrons around the central metal atom. As one of the two benzene molecules donates fewer electrons to a central atom, the whole structure is better stabilized. The present results provide a possible explanation of why graphene tends to grow in a few layers on the Ni surface, while on the Cu surface the weak interaction between the copper

*E-mail: [email protected]. Notes

The authors declare no competing financial interest.

’ ACKNOWLEDGMENT This work was supported by NRF (National Honor Scientist Program, 2010-0020414; WCU, R32-2008-000-10180-0) and KISTI (KSC-2011-G3-02). ’ REFERENCES (1) Fischer, E. O.; Hafner, W. Z. Naturforsch. 1955, 10b, 665. (2) Ray on, D.; Frenking, G. Organometallics 2003, 22, 3304–3308. (3) Haaland, A. Acta Chem. Scand. 1965, 19, 41–46. (4) Albrecht, G.; F€orster, E.; Sippel, D.; Eichkorn, F.; Kurras, E. Z. Chem. 1968, 8, 311. (5) Ngai, L. H.; Stafford, F. E.; Sch€afer, L. J. Am. Chem. Soc. 1969, 91, 48–49. (6) Bochmann, M. Organometallics 2, Complexes with TM-Carbon π bond; Oxford Science Publication: Oxford, U.K., 1994. (7) Choi, K.-W.; Choi, S.; Sun, J. B.; Kim, S. K. J. Chem. Phys. 2007, 126, 034308. (8) Xiang, H.; Yang, J.; Hou, J. G.; Zhu, Q. J. Am. Chem. Soc. 2006, 128, 2310–2314. (9) Aspley, C. J.; Boxwell, C.; Buil, M. L.; Higgitt, C. L.; Long, C.; Perutz, R. N. Chem. Commun. 1999, 11, 1027–1028. (10) Muetterties, E. L.; Bleeke, J. R.; Wucherer, E. J. Chem. Rev. 1982, 82, 499–525. (11) Rayane, D.; Allouche, A.-R.; Antoine, R.; Broyer, M.; Compagnon, I.; Dugourd, P. Chem. Phys. Lett. 2003, 375, 506–510. (12) Yasuike, T.; Yabushita, S. J. Phys. Chem. A. 1999, 103, 4533– 4542. (13) Jones, R. H.; Doerrer, L. H.; Teat, S. J.; Wilson, C. C. Chem. Phys. Lett. 2000, 319, 423–426. (14) Ketkov, S. Y.; Selzle, H. L.; Schlag, E. W.; Domrachev, G. A. Chem. Phys. Lett. 2003, 373, 486–491. (15) Samuel, E.; Caurant, D.; Gourier, D.; Elschenbroich, Ch.; Agbaria, K. J. Am. Chem. Soc. 1998, 120, 8088–8092. (16) Calucci, L.; Cloke, F. G. N.; Englert, U.; Hitchcock, P. B.; Pampaloni, G.; Pinzino, C.; Puccinid, F.; Volpe, M. Dalton Trans. 2006, 4228–4234. (17) Ketkov, S. Y.; Green, J. C.; Mehnert, C. P. J. Chem. Soc., Faraday Trans. 1997, 93, 2461–2466. (18) Xiang, H.; Yang, J.; Hou, J. G.; Zhu., Q. J. Am. Chem. Soc. 2006, 128, 2310–2314. (19) Choi, K.-W.; Ahn, D.-S.; Lee, S.; Kim, S. K. J. Phys. Chem. A. 2004, 108, 11292–11295. (20) Choi, K.-W.; Choi, S.; Ahn, D.-S.; Han, S.; Kang, T. Y.; Baek, S. J.; Kim, S. K. J. Phys. Chem. A. 2008, 112, 7125–7127. (21) Choi, K.-W.; Choi, S.; Baek, S. J.; Kim, S. K. J. Chem. Phys. 2007, 126, 034308. 103

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